KR100910001B1 - Node-b/base station rake finger pooling - Google Patents

Abstract

The Node-B / base station receiver includes at least one antenna for receiving the signals. Each finger in the pool of relocatable rake fingers restores the user's multipath component and is assigned the user's code, the code phase of the multipath component and at least one antenna. The antenna / lake finger pull interface provides each finger of the rake pool with the output of the antenna assigned to that rake finger. The combiner combines the multipath components reconstructed for the user to generate the user's data.

Description

NODE-B / BASE STATION RAKE FINGER POOLING}

1 illustrates a simplified wireless code division multiple access communication system.

2A, 2B and 2C illustrate various sector / cell loads.

3 shows a softer handover.

4 is a simplified block diagram of a preferred Node-B / base station receiver.

5 shows a preferred rake finger.

6 is a simplified block diagram of an alternative preferred Node-B / base station receiver.

7 illustrates a combination of multipath components of a user.

8 illustrates multipath component combining of a user who is undergoing softer handover.

9A, 9B and 9C illustrate the scalability and flexibility of a Node-B / base station receiver.

FIELD OF THE INVENTION The present invention relates generally to radio code division multiple access communication systems, and more particularly to receiving user signals in such systems.

1 illustrates a simplified wireless code division multiple access communication system. Each base station (20: 20 ₁ -20 ₄₎ is a user equipment (UE) in the cell (24 ₁ -24 ₂₎ communicates with a (22, 22 ₁ -22 _21). 1, the base station (20 ₁₎ is in communication with a user equipment (22 ₁ -22 ₉₎ in the cell (24).

Each cell 24 is also a six sectors (26, 26 ₁ -26 ₆₎ As shown in Figure 1 can be divided into. Typically, base stations 20 communicate with each sector 26 using one or more antennas assigned to those sectors 26. Each UE 22 in one sector 26 communicates with an antenna of that sector.

Not only the distribution of the UE 22 within the cell 24 and the sector 26, but also the cell and sector load vary. 2A, 2B and 2C show variations in cell and sector load. 2A shows three lightly loaded sectors that are evenly distributed. The UEs 22 in each sector 26 are distributed relatively uniformly. 2B shows the lightly loaded cell 24 where the UE is unevenly distributed. A sector (26, ₃₎ has no user (no UE) in, and one sector (26 ₂₎ has a number of users. 2C shows overloaded cells 24 that are unevenly distributed. A sector (26, _3), there are a small number of users, and there are many different user sectors (26 _1, 26 _2). The base station / node-B receiver preferably needs to accommodate all these various loads.

In addition, the UE 22 may move between sectors 26, as shown in FIG. 3, for example, from sector 26 ₂ to sector 26 ₁ . One technique for transferring the processing of the UE 22 between two sectors 26 ₁ , 26 ₂ is softer handover. In this softer handover, during its movement period, the UE 22 communicates simultaneously with the antennas of the two sectors 26 ₁ , 26 ₂ . In order to improve signal quality during softer handover, it is desirable for the Node-B / base station receiver to accept the combination of communications received by each sector 26.

Therefore, it would be desirable to have a Node-B / base station receiver capable of handling these varying conditions.

The Node-B / base station receiver includes at least one antenna for receiving the signals. Each finger in the pool of reconfigurable Rake fingers restores the user's multipath component and is assigned an antenna of the user's code, the code phase of the multipath component and at least one antenna. The antenna / lake finger pull interface provides each finger of the rake pool with the output of the antenna assigned to that rake finger. The combiner combines the multipath components received for the user to generate the user's data.

4 is a simplified block diagram of a preferred base station / node-B receiver for one cell. The cell 24 has M sectors _{(26: 26 1 - 26 m} ) is divided into. M can be any value, but preferred values for M are 6, 3, and 1. Each sector 26 has N antennas 28 (28 ₁₁ -28 _IN ) to (28 _M1 -28 _MN ) for receiving user communication in the sector 26. N can be any number and the number can vary from sector to sector, but the preferred values for N are 1, 2 and 4.

Antennas 28 for all sectors 26 are connected to the antenna / lake finger pull interface 30. The interface 30 has the antenna output RAKE finger processor (Finger) (32: 32 _{1-32 0)} Rake finger pool and connected to. Each rake finger 32 is assigned the received multipath components of a particular user to reconstruct. In order to recover its components, each rake finger 32 is assigned an antenna 28, the code and code phase associated with that receiving component. The antenna 28 in the sector 26 where the UE 22 resides is connected to the rake finger 32 via the antenna / lake finger pull interface 30. The code used by the UE 22 is provided not only for the rake finger 32 but also for the code phase of certain multipath components. The rake finger 32 restores the multipath component and weights that component before it is combined with other multipath components of the user.

5 illustrates a preferred rake finger 46 that can be used to implement other rake fingers. Finger 46 receives samples of the signal received from its antenna 28. Path tracker 40 aligns finger 46 with its code phase. Despreader / descrambler 38 despreads and descrambles the received sample into its corresponding user code to restore its user data by the contribution of the multipath component. The path tracker 40 also tracks the path and corrects sampling errors through interpolation, such that, for example, the despreader / descrambler 38 input is always well sampled. The contribution is weighted by the complex weighting device 42 to optimize the combination of the plurality of components. Preferably, even though other weighting algorithms are used, such weighting is performed by maximal ratio combining (MRC). Signal-to-noise ratio (SNR) estimator 44 estimates the SNR of the multipath component to use in its weighting and combining algorithm. The calculation mechanism for calculating the weighting factor w is preferably local to the rake finger 46. In this embodiment a path weighting generator 43 is provided. The path weighting generator typically operates based on the data components of the despread signal. However, it is important to note that decision feedback may be used to cause the rake finger 46 to operate based on the data component of the despread signal.

Referring again to FIG. 4, each finger 32 preferably operates separately from other fingers, and assigns the assigned antenna 28, code, and code phase to any other antenna 28, code, And code phase. This separation and reconstitution capability allows the rake finger pool to be used in a variety of environments. This separation and reconfigurability also facilitates the implementation of the finger 32 using a compact design which is a very big advantage in an application specific integrated circuit (ASCI). For ASICs with clock rates above the chip rate, each reconfigurable rake finger 32 may be used to process a plurality of components. For example, for a 16 times chip rate clock, 16 multipath members may be processed by the same relocation rake finger during the chip period.

Since the output of the rake finger 32 has a varying code phase delay, the synchronization buffer 34 is used to synchronize the rake finger output before combining. Preferably, synchronization buffering is performed using a common memory. In an alternative embodiment, as shown in FIG. 6, buffering is performed prior to inputting the samples to the rake finger pool, such that the output of each rake finger 32 is synchronized prior to engagement.

After synchronization of each Rake finger output, the multipath components of each UE are combined by combiner 36 to generate soft codes for that user (User 1 data-User 2 data). 7 shows the coupling for a user present in sector K26 _K. For each of the N antennas 28 _K1 -28 _{KN in the} sector K26 _K , even if the number of multipath components coupled to each antenna 28 varies, L multipath components [multipath components K11-K1L ) To (KN1-KNL)] are combined. The NxL components are combined by a combiner such as adder 46 to generate user data.

8 shows a bond for a user being handed off by softer handover between sector J26 _J and sector K26 _K. In softer handover, the user moves between two sectors 26. During this movement, the user communicates with two sectors 26. For each of the N antennas (28 _K1 -28 _KN ), 28 _J1 -28 _JN ) in sector (J, K), the L multipath components are combined by combiner 48 generating user data.

Reconfiguration of the Node-B / base station receiver allows for dynamic cell load and user distribution. Reconstruction of the rake finger 32 allows the assignment of the finger 32 where needed. For one cell with users distributed evenly among the sectors, the rake finger 32 may be uniformly assigned to each sector 26. For cells with sectors that are heavier than other sectors, more fingers may be assigned to sectors of heavier load. In addition, more rake fingers 32 may be assigned to users who request a higher quality of service than other users.

9A, 9B, and 9C illustrate the scalability and flexibility of a Node-B / base station receiver. As shown in Figure 9a, initially, the cell 24 is not sectorized under light load is adjusted as a whole by a single ASIC (52 _1). As the cell load increases, as in FIG. 9B, cell 24 is sectored into three sectors 26 ₁ , 26 ₂ , 26 ₃ . The flexible reconfigurability of the rake finger 32 allows the same ASIC ₅ 2 to be used for the sectorized cells. This rake finger 32 is assigned to users in other sectors by modification by software 50 of the antenna / lake pull interface 30. If the cell load increases as shown in FIG. 9C, additional ASICs 5 ₂ can be added to increase the total number of available Rake fingers 32. This addition of ASIC 5 ₂ can utilize a Node-B / base station receiver.

Preferably, for a receiver having a plurality of ASICs 52, each user is assigned to a specific ASIC 52 for processing that facilitates combining across sectors for soft handover. Preferably, since none of the rake fingers 32 are assigned to the sectors 26, the components received by the user from the plurality of sectors 26 can be easily combined. This coupling force of the plurality of sector components facilitates softer handover as shown in FIG. 8. Alternatively, ASIC 52 may be assigned to each sector 26. However, in the case of using softer handover for an ASIC 52 that is uniquely assigned to one sector 26, an interface is used that combines the parts of the user equipment that experience softer handover.

According to the present invention, a base station / node-B receiver can accommodate any of a variety of loads, and the node-B / base station receiver accepts a combination of communications received by each sector 26 to signal quality during softer handover. Can be improved.

Claims (21)

For a Node-B receiver, At least one antenna for receiving a signal; A pool of reconfigurable rake fingers, each rake finger recovering a user's multipath component and being assigned one of the user's code, the code phase of the multipath component, and the at least one antenna. A pool of reconfigurable rake fingers; An antenna / lake finger pull interface for providing each finger of the rake finger pool with an output of an antenna assigned to the finger; And And a combiner for combining the reconstructed multipath components of the user to produce data related to the user. The Node-B receiver of claim 1, wherein each of the at least one antenna is associated with a separate sector. 2. The Node-B receiver of claim 1 further comprising a path tracker for aligning each finger having its code phase. 2. The Node-B receiver of claim 1, further comprising a despreader / descrambler that despreads and descrambles the received signal with a corresponding user code to restore the contribution of a multipath component to the received signal. 4. The Node-B receiver of claim 3 wherein the path tracker also tracks the path and corrects sampling errors through interpolation. The Node-B receiver of claim 1 wherein each reconfigurable rake finger operates separately from other reconfigurable rake fingers. The Node-B receiver of claim 1, wherein each reconfigurable Rake finger is capable of reconfiguring the assigned antenna, code, and code phase to any other antenna, code, and code phase. The Node-B receiver of claim 1 wherein the fingers are implemented using a compact design. 3. The Node-B receiver of claim 2 wherein more rake fingers are assigned to sectors with higher loads. 3. The Node-B receiver of claim 2 wherein the rake fingers are uniformly distributed among the sectors. delete delete delete delete delete delete delete delete delete delete delete

Images